Experimental evaluation of simple estimators for humanoid robots

T. Flayols, A. Prete, Patrick M. Wensing, Alexis Mifsud, M. Benallegue, O. Stasse
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引用次数: 32

Abstract

This paper introduces and evaluates a family of new simple estimators to reconstruct the pose and velocity of the floating base. The estimation of the floating-base state is a critical challenge to whole-body control methods that rely on full-state information in high-rate feedback. Although the kinematics of grounded limbs may be used to estimate the pose and velocity of the body, modelling errors from ground irregularity, foot slip, and structural flexibilities limit the utility of estimation from kinematics alone. These difficulties have motivated the development of sensor fusion methods to augment body-mounted IMUs with kinematic measurements. Existing methods often rely on extended Kalman filtering, which lack convergence guarantees and may present difficulties in tuning. This paper proposes two new simplifications to the floating-base state estimation problem that make use of robust off-the-shelf orientation estimators to bootstrap development. Experiments for in-place balance and walking with the HRP-2 show that the simplifications yield results on par with the accuracy reported in the literature for other methods. As further benefits, the structure of the proposed estimators prevents divergence of the estimates, simplifies tuning, and admits efficient computation. These benefits are envisioned to help accelerate the development of baseline estimators in future humanoids.
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类人机器人简单估计器的实验评价
本文介绍并评价了一种新的简单估计方法,用于重建浮基的姿态和速度。对于依赖于高速率反馈全状态信息的全身控制方法来说,浮基状态的估计是一个关键的挑战。虽然接地肢体的运动学可以用来估计身体的姿态和速度,但地面不平整、脚滑和结构灵活性造成的建模误差限制了仅从运动学估计的效用。这些困难促使传感器融合方法的发展,以增加运动测量的车载imu。现有的方法通常依赖于扩展卡尔曼滤波,这种方法缺乏收敛保证,并且可能存在调谐困难。本文对浮点基状态估计问题提出了两种新的简化方法,即利用现成的鲁棒方向估计器来引导开发。用HRP-2进行原地平衡和行走的实验表明,简化后的结果与文献中报道的其他方法的准确性相当。作为进一步的好处,所提出的估计器的结构防止了估计的分歧,简化了调优,并允许有效的计算。预计这些好处将有助于加速未来类人机器人基线估计器的开发。
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